DE4445814A1 - Electrical power generator for road vehicles - Google Patents

Abstract

The self-diagnostic system is used to check the condition of the electric power generation system of a road vehicle. The generator (1) has an armature winding (11), 3 phase full wave rectifier (12), and a field winding (13). The output is received by voltage regulator (2) coupled to a charge bulb (3), engine ignition switch (4) and the battery (5) to which is coupled a load (6). Built into the voltage regulator is a micro computer based diagnostic unit (86) that checks for anomalies and stores them in memory for evaluation by service personnel.

Description

The present invention relates to a charging generator Self-diagnosis function, particularly preferably on a charging generator for a vehicle driven by an internal combustion engine a self-diagnosis function.

It is known that in a conventional diagnostic device one Charge generator systems, such as. B. an alternator, such as be wrote in Japanese Patent Application Laid-Open 195 436/1983, Total information about different parts of a charging generator system be melted and that the charge generator system is diagnosed and that the diagnostic results are immediately displayed on a display device become. The above-mentioned conventional diagnostic device can send an alarm to an operator when abnormalities are detected and this will be in case of detection of various anomalies ten continued in a charge generator system. However, an operator can sometimes fail to recognize an alarm because the alarm only generates once when the abnormality has occurred under special conditions. Therefore, the conventional diagnostic devices are not sufficient useful for a maintenance person or an inspector.

The present invention is in view of that described above Problems have been achieved and aim at supporting an affirmation of the  Situation of occurrence of an abnormality in a charge generator system as well as clarifying the anomalies by at least informa tion of the abnormality and the content of the abnormality in a memory facility is maintained when the abnormality occurs and by the stored content by an input signal from outside the loading area rators is issued by the present invention, depending on the Erfor dernis.

It is a further object of the present invention, the charging generator system to diagnose more precisely and the information about the loading gene rator system in succession to an operator and continue a maintenance person or an inspector the information currently available point of occurrence of the abnormality by typing and Control circuit output signals using diagnostics circuit are monitored, with both circuits in one charge generator with diagnostic device by the present invention be put.

It is another object of the present invention to save the Data related to a charge generator or a voltage setting unit and to report the occurrence of an abnormality situation Easier to hand over to a maintenance person or an inspector, by an information processor, such as. B. a personal computer with the Diagnostic circuit is connected as required.

It is a feature of the present invention, at least one group of abnormality data and abnormality content and the contents output data using an output device, being an input of a specific signal from outside the front direction is detected by the present invention when the contents  NEN data are needed, namely in the charging generator with a Self-diagnosis function, which is a self-diagnosis device, a memory device and an output device. Through the above he mentioned feature can support the function of self-diagnosis the confirmation of the occurrence of an abnormality situation and the complaints anomalies.

The self-diagnosis device mentioned above makes it possible to at least the anomaly data or the anomaly contents in one memory according to the occurrence of the abnormality in the device of the present invention and the contents of the memories output direction by such a specific input signal of a specific voltage or a specific impulse as required is detected.

Further advantages, features and possible uses of the present the invention result from the following description of Embodiments in connection with the drawing. In the drawing show:

Fig. 1 is a circuit diagram of a charging generator in an exemplary embodiment from the present invention.

Fig. 2 is a configuration diagram of a self-diagnosis device in an embodiment of the present invention.

Fig. 3 is a flowchart of the self-diagnosis process in an exemplary embodiment from the present invention.

Fig. 4 is a flowchart of the process of outputting the stored data in an embodiment of the present invention.

Fig. 5 shows an example display format of a display device in an embodiment of the present invention.

Fig. 6, the areas in the frequency domain voltage for separating the input control signals in an embodiment of the present the invention.

Fig. 7 shows an example waveform of an input signal from the outside in an embodiment of the present invention.

Fig. 8 shows an example waveform of an input signal mode in one embodiment of the present invention.

Hereafter, details of the present invention are based explained by embodiments, referring to the drawings relates.

Fig. 1 is a circuit diagram of a charging generator with a self-diagnosis function, installed in a vehicle, comprising a generator 1 , an armature winding 11 , a three-phase full-wave rectifier 12 for converting alternating currents generated in the armature winding 11 into direct currents and one Field winding 13 . Furthermore, the reference numerals mean the following items of equipment, ie reference numeral 2 is a voltage setting unit, 3 is a charging lamp, 4 is an engine key switch, 5 is a battery charged by the generator 1 for feeding currents to an external load 6 via a switch 6 a, 7 is a display device (CRT), 8 is a motor control unit, and 9 is a personal computer.

The voltage setting unit 2 is explained in detail below. Reference numeral 21 denotes a flywheel diode in order to conduct a return current to the terminal B when a power transistor 22 for driving a field winding 13 switches from the off to the on state. Reference numeral 23 denotes a power transistor for driving a charging lamp 3 . Numeral 24 is a field weakening resistor for detecting a field current, and numeral 25 denotes a control circuit for driving the on-off operations of the power transistor. The reference numeral 26 denotes a self-diagnosis circuit. Numeral 27 denotes the terminal C for inputting a control signal to control the voltage setting from outside the present charge generator (hereinafter referred to as the C terminal), and numeral 28 denotes an output terminal for outputting the information from the self-diagnosis circuit 26 mentioned above to one outer personal computer 9 .

Fig. 2 shows a diagram of the internal structure of the self-diagnosis circuit 26 , the z. B. is connected to a microcomputer. The self-diagnosis circuit 26 shown in the figure has a CPU 261 for calculation, a RAM 262 which is used for data storage and calculation, a ROM 263 for storing programs and a writable ROM 264 for which a non-volatile memory is used. Furthermore, the circuit has an I / O register 265 for inputting signals from the C terminal 27 and the information about the load register system, an I / O register 266 for outputting the control signals of the power transistor 23 , the signals being on a CRT 7 are displayed and the signals are sent to the external personal computer 9 , and a BUS line 267.

The operations of the embodiment having the above-mentioned structure will now be described with reference to FIGS. 3 and 4. Fig. 3 is a flowchart showing the operations of the embodiment in the normal state. First, by turning a key switch of an engine, the voltage setting unit 2 is started and the programs in the ROM 263 are executed. Next, excitation currents are allowed to flow into the field winding 13 by on-off control of the power transistor 22 at a constant conduction rate through the control circuit 25 , and the charge lamp is turned on. Then the generator 1 is driven by a generator drive belt (not shown in the figures) which is guided around the engine, and the generator 1 is driven by starting the engine, and alternating currents are induced in the armature winding 11 and to the battery 5 , the voltage setting unit 2 , the external loads or consumers 6 , etc., after they have been rectified by the three-phase full-wave rectifier 12 . At the same time, the start of the operation of the generator 1 is detected by the control circuit 25 , and the power transistor 23 is switched to the non-conductive state, and the charge lamp is switched off. The voltage control of controlling the conduction rate of the power transistor 22 to obtain the optimum output voltage is started by detecting the terminal voltage of the battery 5 . In the above-mentioned generator states, information about the charging generator system, such as e.g. B. number of revolutions of the generator, output voltage of the generator, field currents etc., taken in a RAM 262. In step 303, the state of the key switch 4 is read out, and if it is in the on state, the process goes to step 304, on the other hand the process ends. In step 304, the various types of information put into RAM 262 are compared to their predetermined value or range, and if it is equal to or falls within the predetermined range, the information about the charge generator system is displayed on the display device 7 is displayed in step 305, and the process ends. Otherwise, it is judged that the information is abnormal and the process goes to step 306.

At step 306, the contents of the abnormality, such as B. Interruption of lines that are wired in the charge generator system, wire detachment at connection terminals, short circuit of the power transistor, slip or interruption of the generator drive belt, etc. judged on the basis of the information determined to be abnormal in step 304, and on the Based on a signal corresponding to the contents of the abnormality, the alarm of an abnormality occurrence is displayed to an operator in step 307 by driving the power transistor 23 and the charging lamp 3 being flashed, and further the contents of the abnormality are also displayed to the operator.

In step 308, the information about the charge generator in the abnormal conditions and the content of the abnormality on a CRT 7 displayed. In step 309, the contents of the ROM 264 are stored stored abnormality in a RAM 262, and the previous ones Content is compared to the current content. If both are equal, the process comes to an end, otherwise they are against current content is stored in ROM 264 and the process opens The End. The process mentioned above is in the preset period performed while the key switch is on. It is then  possible to save the content of the abnormality in time series and the Offer information to confirm the situation when it occurs an abnormality and useful for querying the cause of the abnormality are.

In FIG. 4 is a flowchart of the output of stored data is shown. In step 402, the signal is sensed at the C terminal and the signal is taken into a RAM 262. In step 403, the sensed signal is compared to the stored data of a digital output mode, and if both are the same, the process goes to step 404, otherwise the process ends.

At step 404, the existence of the data stored in the ROM 264 is confirmed, and if the ROM contains no data, the process ends. Otherwise, in step 405, the stored data is displayed on a CRT 7 in the form shown in FIG. 5 or output to a personal computer 9 through the output port 28 , then the process goes to step 404. The above is the process for the Data output mode, through which the stored data can be easily output.

A supplementary explanation of step 403 will now be described. In the embodiment, since the data output mode signal to request the self-diagnosis circuit 26 to output the stored data to the C terminal, it is necessary to distinguish the signals input to the C terminal which the signal for controlling the voltage setting from the outside (referred to as an external control signal) is also input. The range of each input signal used is shown by the voltage frequency space in FIG. 6. In the figure, the area a is used by the outer control signal, and a signal which differs from the outer control signal in at least the voltage or the frequency can be selected as the output mode signal in the area b. If e.g. B. the signal with a working level of VA volts and a constant Peri ode t, as shown in Fig. 7, is used for the external control signal, the signal in area b, as shown in Fig. 8, used for the output mode signal become. Since the external control signal differs from the output mode signal in both voltage and frequency, it is easy to distinguish between the two signals.

Then, in the embodiment, by setting the voltage VB of the output mode signal to the terminal voltage of the battery 5 and only connecting the C terminal and the terminal of the battery 5 , the stored data is easily taken out without using any special device.

Furthermore, although a cathode ray tube (CRT) is used as the display device in the embodiment, it need not be mentioned that any display device such as a. B. a liquid crystal panel, an LED panel, etc., can be used. If a display device of a navigation system is also used as that of this self-diagnosis circuit, the self-diagnosis function can be built into one of the functions of a navigation system. In this case, it is possible to realize a system in which diagnosis results and the information about the charging generator system which are sent from the self-diagnosis circuit 26 are displayed by selecting the self-diagnosis on a menu screen of the navigation system, thereby outputting the mode signal of the stored Data is sent from the navigation system to the self-diagnosis circuit 26 via the C connection 27 .

It is an effect of the present invention to an operator To give an alarm about the occurrence of an abnormality and a war to give support or an inspector support with the confirmation due to the occurrence of an abnormality and when examining the Cause of the abnormality by realizing a charging generator at the abnormality state in it easily from the outside by a simple one Facility can be read out.

It is another effect of the present invention, a more precise one Execute self-diagnosis, and information about the charging generator system in succession to one operator and still one Maintenance person or an inspector the information at the time of Occurrence of the abnormality by giving input and output signals a control part are monitored using a diagnostic part, both parts in a charging generator with a diagnostic device of the present invention.

It is another effect of the present invention to dispense the stored content regarding the charging generator or the span Simplification adjustment unit and the occurrence of an abnormality situation easier to hand over to a maintenance person or an inspector ben by an information processor; such as B. a personal computer; ever is connected as needed.

Claims (11)

1. charging generator comprising a motor-driven generator having an armature winding and a field winding, a voltage adjusting unit for setting an output voltage of the generator by controlling field currents of the field winding, and a battery which is charged by the output of the generator, the generator having:
a self-diagnosis device installed in the voltage setting unit for diagnosing a control circuit of the voltage setting unit;
a storage device for storing data about states of the charge generator including diagnostic results, the storage device being provided in the self-diagnosis device; and
an output device for outputting data stored in the results of the storage device from the self-diagnosis device by inputting an output request signal for the stored data from outside the charging generator. 2. charging generator with self-diagnosis function according to claim 1, wherein the self-diagnosis device has an input signal connection and means for discriminating the input of the output request signal for stored data to the input terminal from an external control signal output of an engine control unit,  which is also input to the input port, and wherein the self-diagnosis device stores the stored data on the basis of the Output request signal for stored data. 3. charging generator with a self-diagnosis function according to claim 1, wherein the storage device has at least data on abnormality states of the charging generator when an abnormality occurs and / - or stores content of the abnormality. 4. charging generator with a self-diagnosis function according to claim 1, the output device of the voltage setting unit at least a display unit for displaying the outputs of the self diagnosis seeinrichtung or a transmission unit for transmitting the Diagnostic results to an output device outside of the drawer has generator. 5. charging generator with a self-diagnosis function according to claim 1, wherein a control circuit of the voltage setting unit is off voltage of the generator controls, by the data over the States of the charge generator including the voltage of the battery rie, the field currents and the number of revolutions of the generator as well receives the external control signal output from the engine control unit, and wherein the self-diagnosis device of the voltage setting unit self-diagnosis using the state data of the charging generator, the control signals from the control circuit are output, and the external control signal executes. 6. charging generator with a self-diagnosis function according to claim 1, wherein the self-diagnosis direction is an information display device device installed in a vehicle for display  the stored data about the states of the charging generator including diagnostic results. 7. charging generator with a self-diagnosis function according to claim 1, wherein the storage device sends the stored data to a Outputs device that is able to process information, and which is connected to the storage device. 8. charging generator with a self-diagnosis function according to claim 1, wherein the storage device has the ability to hold the stored saved data even in the event of a power source interruption. 9. charging generator, which has a generator which is driven by a motor for feeding currents to consumers, a voltage setting unit for setting an output voltage of the generator by controlling field currents of the field winding and a battery which is charged by the output of the generator the generator has:
a self-diagnosis device installed in the voltage setting unit for diagnosing a control circuit of the voltage setting unit; and
a storage device for storing data on states of the charging generator including diagnostic results, the storage device being provided in the self-diagnosis device, the stored data being able to be read out in a state in which the voltage setting unit is removed from a vehicle. 10. charging generator, which has a generator which is driven by a motor for feeding currents to consumers, a voltage setting unit for setting an output voltage of the generator by controlling field currents of a field winding and a battery which is charged by the output of the generator the generator has:
a self-diagnosis device installed in the voltage setting unit for diagnosing a control circuit of the voltage setting unit;
a storage device for storing data about states of the charge generator including diagnostic results, the storage device being provided in the self-diagnosis device;
an information display device installed in a vehicle for displaying the stored information; and
an output device for outputting the stored data to a device outside the vehicle, which is connected to the self-diagnosis device. 11. charging generator with a self-diagnosis function according to claim 9 or 10, wherein the storage device consists of non-volatile memories is formed.